KR100621577B1 - Method and apparatus for power managing for portable computer system - Google Patents

Abstract

A power management method and apparatus for a portable computer system providing a convenient user interface are provided.

The power management method of a portable computer system includes calculating a range of desired time of use by using power consumption and remaining battery power at the lowest power level of the portable computer system, the calculated range of desired time of use, and user desired use. Providing a desired use time input box for inputting a time, receiving a desired use time from a user through the desired use time input field, and adjusting a power level of the portable computer system according to the input desired use time; Resetting.

Power, graphical user interface, battery, time

Description

Power management method and apparatus for portable computer system {Method and apparatus for power managing for portable computer system}

1 is a diagram illustrating a user interface for power management according to an embodiment of the present invention.

2 is a diagram illustrating a user interface for power management according to another embodiment of the present invention.

3 is a flowchart illustrating a power management process according to an embodiment of the present invention.

4 is a flowchart illustrating a power level reset process in detail according to an embodiment of the present invention.

5 is a flowchart illustrating a device power mode reset process in more detail according to an embodiment of the present invention.

6 is a flowchart illustrating a power management process according to another embodiment of the present invention.

7 is a block diagram showing the configuration of a power management device of a portable computer system according to an embodiment of the present invention.

The present invention relates to power management of a portable computer system, and more particularly, to a power management method and apparatus for a portable computer system that provides a convenient user interface.

Often users need to use a portable computer in a mobile environment. Computers in a mobile environment will not be able to use conventional AC power. In this situation, rechargeable battery power is generally used instead of AC power. The energy stored in the battery is in proportion to the weight of the battery. In other words, to store a lot of energy, the weight of the battery must be heavy. Therefore, there have been many studies for increasing the energy density of the battery and increasing the stability of the battery. Based on these findings, batteries known to date include nickel-cadmium (NiCd), nickel-metal-hydride (NiMH), lithium-ion (Li +), and lithium polymer batteries. In addition, fuel cell technology is being studied for use as a computer power source in a mobile environment. Using a good battery or using more batteries can increase the amount of computing time available in a mobile environment, but high-density batteries are expensive and inevitably increase the weight of a portable computer system when using many batteries. . In particular, increasing weight of a portable computer system is a deterrent to mobility, which is an advantage of the portable computer system.

Accordingly, methods for maximally suppressing unnecessary power usage through power management of portable computer systems are being researched or developed. Korean Patent Laid-Open Publication No. 2002-0080615 relates to a method for managing battery power in a portable computer. The multi-step mode is used to calculate and display how long a specific function designated by a user can be performed with a current battery level. By selecting and specifying any one of the modes, it is possible to select or variably adjust the execution time for a specific function, thereby effectively limiting the unnecessary consumption of battery power by a configuration means that is not critical for performing a specific function. It also allows to extend the execution time for a specific function.

In addition, Japanese Patent Laid-Open No. 1999-143595 measures the power of a device for which power saving setting is possible and a device for which power consumption cannot be set, and based on the measured value, the power consumption value is written on the recording medium and modified from time to time. Then, based on the remaining power of the current battery and the current power saving setting level obtained from the recording medium, the power consumption of each device and the power consumption not determined by the power saving setting are used, and the operating time by the remaining power of the battery is estimated. Output

As such, these approaches can significantly reduce the battery life of portable computer systems by minimizing unnecessary battery usage. In many cases, however, the user wants to have the time needed for the particular task desired by the user through the computer system rather than simply managing the battery power to increase the usable time of the computer system. In other words, the user may not feel the need to manage the power supply of the portable computer system if he can perform the desired task with the remaining power of the current battery. In addition, even when there is a need for power management, a user may want to secure the required computing time by simply setting a desired time rather than securing the computing time through a complicated selection.

Korean Patent Laid-Open No. 2001-0096576 discloses that when a user inputs an amount of time required to drive a data processing system, it is required to identify the amount of available power and to operate the data processing system for the amount of time input using the available power. Identify the power usage of the data processing system and set the data processing system to the power usage. By doing so, the user can use the data processing system for a desired time. However, the invention disclosed in 2001-0096576 does not set a limit on the time a user can enter. For example, the disclosed invention does not provide information that the maximum input time is 2 hours to the user when the maximum input time is 2 hours. Accordingly, when the user enters 3 hours, the user does not achieve the purpose and only receives a warning message.

Accordingly, it would be beneficial to provide a method and apparatus for portable computer power management with a convenient interface while providing a limitation of the time available to the user.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described needs, and an object of the present invention is to provide a power management method and apparatus for a portable computer system that provides a convenient user interface.

The objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the power management method of a portable computer system according to an embodiment of the present invention comprises the steps of calculating the range of desired time using the power consumption and the remaining battery amount at the lowest power level of the portable computer system; Providing a usage time input field for allowing the user to input the desired usage time range and the user desired time input; receiving input of the usage time from the user through the usage time input field; and Resetting the power level of the portable computer system in accordance with the input desired usage time.

In order to achieve the above object, the power management device of a portable computer system according to an embodiment of the present invention provides a user with a range of desired time calculated using power consumption and remaining battery power at the lowest power level of the portable computer system. A user graphical interface including a desired time of use input box for providing and inputting a desired time of use at the user's option; and a total user time including the desired time of use received via the user graphical interface is left in the battery. And a power manager that resets the power level of the portable computer system to time out.

In order to achieve the above object, a portable computer system according to an embodiment of the present invention, the battery unit for supplying power, a plurality of devices each providing a predetermined function, the power consumption and the remaining power at the lowest power level of the system A user graphical interface including a usage time input field for providing a user with a range of desired usage time calculated using a battery amount and allowing input of a desired usage time according to a user's selection, and input via the user graphical interface And a power manager that gradually reduces the power level of each device until the total user time including the received desired usage time exceeds the remaining time of the battery unit.

Specific details of other embodiments are included in the detailed description and the drawings.

Advantages and features of the present invention and methods for achieving them will be apparent with reference to the embodiments described below in detail with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but can be implemented in various different forms, and only the embodiments make the disclosure of the present invention complete, and those of ordinary skill in the art to which the present invention belongs. It is provided to fully inform the person having the scope of the invention, the invention is defined only by the scope of the claims.

The portable computer system used in the present invention is a system having a computing function, including a plurality of devices that operate under battery power and perform respective functions of a CPU, a display device, and a storage device. The portable computer system includes a battery, which allows the user to use it while moving, and may also use general AC power in addition to the battery power during standstill. An example of such a portable computer system is a notebook computer, and may include a PDA or a mobile phone having a computing function.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 are diagrams illustrating a user interface for power management according to an embodiment of the present invention, respectively. In the user interface for power management, the user enters a user desired time (hereinafter referred to as "use time"), and the power management device adjusts the power level of the portable computer system to ensure desired use time with the current battery level. To do it. As used herein, the term "desired time of use" refers to the concept of time that the user wants to add from the current battery remaining time and the time that the user actually wants to use (the sum of the current battery remaining time and the time that the user wants to add, hereinafter It may be interpreted as including the concept of "total user time". In the following embodiment, the desired use time is described as a time to be added by the user. However, this is merely an example, and the technical spirit of the present invention includes the latter case.

First, referring to FIG. 1, a user interface is provided to a user in the form of a graphical user interface (GUI). The user interface includes a pre-input battery information field 110 indicating a power state before the user inputs additional time, a time input field 120 in which the user can input additional time, and a maximum additional time information field 130. And, after the input includes a battery information column 140.

The battery information field 110 before input is provided to the user in an inactive state, and may include information such as a current remaining battery amount and a remaining time available for the current remaining battery.

The limit of additional time that a user can enter is provided through the highest additional time input field 130. The maximum addable time information field 130 is provided to the user in an inactive state, and indicates to the user the best time that can be added currently.

The user may recognize a range of desired time through the battery information field 110 and the maximum additional time input field 130 before the input.

The time input column 120 is provided to the user in an activated state, and the user may input a time to be additionally secured through the time input line 120. In one embodiment, the time input box 120 includes a text box 121, and a user may input a time to be additionally secured using the text box 121. In another embodiment, the time entry 120 includes a slider 123 that allows the user to select an additional time value between the lowest addable time 124 and the highest addable time 125. The user may click and drag the slider bar 122 with the mouse on the slider 123 to select a desired additional time. In another embodiment, the time input field 120 includes both a text box 121 and a slider 123, and the slider bar 122 automatically turns on when the user enters an additional time in the text box 121. Move to the corresponding additional time position on slider 123. On the other hand, when the slider bar 122 is moved to a specific additional time portion of the slider 123, the additional time is automatically written in the text box 121.

Time entry 120 may further include at least one or more checkboxes for specifying priorities that reduce power levels of the devices. For example, when watching a movie, the brightness of the LCD may be important, in which case the user may click on the LCD checkbox 126 to select it. If the LCD checkbox 126 is selected, when lowering the power level of the devices in order to secure a user addition time of 30 minutes, the power level of other devices is first adjusted, and the power level adjustment of the LCD is finally performed. Similarly, when a specific program needs to be installed on the hard disk, the user checks the HDD checkbox 127 with a mouse. On the other hand, when watching a movie through a CD-ROM or DVD-ROM, the power level of optical drive such as a CD-ROM drive or a DVD-ROM drive should be avoided as much as possible. The user can move the ODD (Optical Device Drive) check box 128 with a mouse. Click to avoid reducing the power level of the ODD. As such, in the present embodiment, if a device is checked through a check box, power level adjustment of the device is avoided as much as possible. In one embodiment, when a device check box is checked, the power level of the device is maintained above a predetermined value. For example, when the LCD checkbox 126 is not checked, the LCD may be turned off to reduce the power level. However, when the LCD checkbox 123 is checked, the LCD power is maintained at 50% or more. . It may not be necessary to power the LCD when listening to music, but it is necessary to supply LCD power when watching a movie. Such a reference value may be set to an appropriate value in advance by a portable computer producer, but may also be set by a user's setting. When the LCD checkbox 126 is checked, the maximum addable time is automatically recalculated. That is, the highest power level calculated based on the case where the LCD power level is 0 must be recalculated based on the 50% of the LCD power level.

After input, the battery information field 140 provides the user with information about the remaining battery amount and the remaining time after the user inputs the additional time.

The user interface may include a confirmation button 150, a cancel button 151, and an apply button 152. If a user enters an additional time or checks a checkbox and clicks the apply button 152 with a mouse, the contents set or changed by the user are stored. When the user clicks the cancel button 151 with a mouse, the contents set or changed by the user are not stored. When the user clicks the confirmation button 150 with a mouse, the contents set or changed by the user are saved and the user interface is terminated.

Next, referring to FIG. 2, a user interface according to another embodiment of the present invention may display a pre-input battery information field 210 indicating a power state before a user inputs an additional time, and the user may input an additional time. It includes the time input field 220, the maximum additional time information field 230, and the battery information field 240 after input. The function of the battery information field 210 and the addable time information field 230 before input is the same as the embodiment of FIG.

The time input box 220 is provided to the user in an activated state as in the embodiment of FIG. 1, and the user may input a time to be additionally secured through the time input box 220. The time entry 220 can optionally or both include a text box 221 and a slider 223. The user interface can also include at least one checkbox 226, 227, 228. The embodiment of FIG. 2 further includes a reliability indicator column 229 in the embodiment of FIG. The user may click and drag the slider bar 222 on the slider 223 with a mouse to select a desired additional time. Substantially selected additional time may not always be guaranteed. This is because the CPU usage may vary depending on the application, and the amount of power used by peripheral devices may vary. Therefore, the present embodiment further includes the reliability according to the additional time obtained by experimenting with the manufacturer statistically for the user to select the additional time. For example, if the maximum addable time is 62 minutes, the user can select the additional time of 62 minutes to indicate that 62 minutes is guaranteed with 75% confidence. That is, when the user selects an additional time of 62 minutes, the user may select about 25% in consideration of the fact that the time selected by the user may not be guaranteed. In other words, according to the present embodiment, the user can select an appropriate additional time necessary in consideration of reliability.

According to the present embodiment, the battery information field 240 after the input may further provide information of reliability, in addition to the information on the remaining battery amount and the remaining time after the user inputs the additional time. That is, the user may determine the current remaining time through the battery information column 240 after inputting the additional time, and can also understand that there is a 91% probability that the current remaining time is guaranteed.

Like the embodiment of FIG. 1, in the present embodiment, the user interface may include a confirmation button 250, a cancel button 251, and an apply button 252.

1 and 2 described above, although the user inputs a desired additional time, an interface of a method of actually inputting a time to be used by the user is also possible. In this case, the maximum available time information field 230 is changed to the maximum available time information field, and the time input field 220 has a text box and a slider for inputting the total user time (current battery remaining time + additional time). Optionally or all may be included.

3 is a flowchart illustrating a power management process according to an embodiment of the present invention.

First, the power level of the computer system is set to the lowest power level (S310). That is, the operating speed of the CPU is set to the minimum, and the power level of the computer system is measured while the power supply of the HDD, the ODD, and the like are cut off.

When the power level of the computer system is set to the lowest power level, the maximum addable time is calculated using the current power consumption and the current remaining battery amount (S320). The highest addable time can be found as the difference between the current battery remaining time at the lowest power level and the battery remaining time at the current power level. The calculated maximum addable time is calculated and then presented to the user.

Then, the user enters an additional time (S330). When the additional time is input, the power level is reset (S340). By resetting the power level below the current power level, additional time entered by the user can be obtained. Resetting of the power level will be described with reference to FIG. 4.

After the power level is reset, the user uses the computer for a desired time (S350).

4 is a flowchart illustrating a power level reset process in detail according to an embodiment of the present invention.

First, the remaining time of the battery at the current power level is calculated (S410). Then, it is determined whether the remaining battery time exceeds the total user time (S420).

Total user time refers to the final time that the user must obtain by entering additional time. For example, if the remaining battery time is 1 hour and the additional time input by the user is 30 minutes, then the total user time is 1 hour 30 minutes.

If the remaining battery time does not exceed the total user time, it is determined whether the state is the lowest power level (S430). If not, the power mode of the device is reset to a power mode lower than the current power mode (S440). The power mode reset of the device will be described later with reference to FIG. 5. After resetting the power mode of the device, the battery remaining time is calculated again (S410). Then again, it is determined whether the remaining battery time exceeds the total user time (S420). If the remaining battery time calculated by gradually lowering the power level of each device through the above process exceeds the total user time, the power mode of each device is set to the power mode corresponding to the power level of each device at this time ( S450). If the remaining time of the battery reaches the lowest power level without exceeding the total user time, the maximum usable time at this time is recalculated (S460). Then, the user is notified of the fact that the portable computer system is inoperable until the total user time and the updated maximum usable time (S470). The user may enter a new additional time with reference to the updated maximum available time.

The embodiment of FIG. 4 resets the power level of the portable computer system while sequentially decreasing the power level of each device in the portable computer system until the current battery remaining time exceeds the total user time. However, this is exemplary and it is also possible to set the initial power level of each device in consideration of the current battery remaining time and the total user time, and then reset the power level of the portable computer system while sequentially reducing the power level of each device. Do. For example, if the current remaining battery time is 1 hour and the total user time is 1 hour 30 minutes, the approximate initial power level of each device of the portable computer such that the power consumption of the portable computer is about 2/3 of the current power consumption. After setting, the process of S410 to S470 may be performed and the final power level of each device of the portable computer may be set.

5 is a flowchart illustrating a device power mode reset process in more detail according to an embodiment of the present invention.

First, it is determined whether the important device is set through the check box (S510).

If the critical device is set, it is determined whether the non-critical device is in the lowest power mode (S520). If the non-critical device is not in the lowest power mode, the power level of the non-critical device is reduced (S530).

If the non-critical device is in the lowest power mode, it is determined whether the critical device is in the reference power mode or more (S540). The reference power mode refers to the lower limit of the power level that can be lowered in the device set as the critical device. For example, when the LCD is an important device, the power mode when the power level of the LCD is 50% is a reference power mode when the LCD is set in advance to maintain the power level of the LCD at 50% or more. However, if the LCD is not a critical device, it is possible for the LCD to have a zero power level. When the critical device is in the reference power mode or more, the power level of the critical device is reduced (S550). When the critical device is in the reference power mode or less, the power level is not reduced.

On the other hand, if the critical device is not set, it is determined whether all devices are in the lowest power mode (S560). If all devices are not in the lowest power mode, the power level of the device that is not in the lowest power mode is reduced (S570). If all devices are in the lowest power mode, the power level is not reduced.

6 is a flowchart illustrating a power management process according to another embodiment of the present invention.

First, the power level of the computer system is set to the lowest power level (S610). That is, the operating speed of the CPU is set to the minimum, and the power level of the computer system is measured while the power supply of the HDD, the ODD, and the like are cut off.

When the power level of the computer system is set to the lowest power level, the maximum addable time is calculated using the power consumption and the remaining battery amount at this time (S620). The maximum addable time can be found as the difference between the remaining battery time at the lowest power level and the remaining battery time at the current power level. The calculated maximum addable time is calculated and then presented to the user.

Then, the user inputs an additional time (S630). When the additional time is input, the power level is reset (S640). By resetting the power level below the current power level, additional time entered by the user can be obtained. Resetting the power level will be described with reference to FIGS. 4 and 4 described above.

After the power level is reset, the user uses the computer for a desired time (S650). While using the computer, the battery remaining time is re-measured at regular time intervals (for example, every 10 minutes) (S660). After re-measuring the remaining battery time, it is determined whether the current remaining battery state can guarantee the total user time (S670). This process is necessary because sometimes the total user time may not be guaranteed due to the remaining battery time obtained by lowering the power level through the power level reset process (S640). For example, the amount of power consumed is increased when the CPU usage of a portable computer system increases rapidly. In such a case, the embodiment of FIG. 3 may not guarantee total user time. However, the present embodiment may further include a process of determining whether the total user time can be guaranteed, thereby ensuring the total user time.

In other words, if it is determined that the total user time cannot be guaranteed, the power level of each device is readjusted through the power level reset process (S640). Then, the user may use a computer (S650). As described above, the power level reset process S640 may be automatically performed without a user's explicit operation.

7 is a block diagram showing the configuration of a power management device of a portable computer system according to an embodiment of the present invention.

The power management device 710 of the portable computer system includes a user graphical interface 712, a power manager 714 and a computational agent 716.

The user graphical interface 712 provides the user with information such as the current battery status and the maximum addable time of the portable computer system, and provides a time entry field for the user to enter additional usage time.

The power manager 714 lowers the power level of each device of the portable computer system so that the remaining time of the battery may be longer than the user time including the user addition time received through the user graphic interface 712. Reset the power level.

The computation agent 716 calculates the highest addable time based on the difference between the battery remaining time at the lowest power level and the battery remaining time at the current power level.

The battery unit 720 of the portable computer system includes a battery 722 for converting chemical energy into electrical energy, and a battery controller 724 for checking a state of the battery and calculating a remaining amount and a remaining time of the battery. The remaining amount and time information of the battery unit 720 is transmitted to the power manager 714.

On the other hand, the power manager 714 controls the power level of the various devices constituting the portable computer system. Examples of devices included in a portable computer system include a speaker 732, an ODD 734, an HDD 736, an LCD 738, a CPU 739, and the like. Each device includes a control for the device. For example, a speaker controller 731 for adjusting the sound volume, a tone, and the like of the speaker 732, an ODD controller 733, and an HDD 736 for controlling operations such as reading, writing, and erasing the ODD 734. And an HDD controller 735 for controlling operations such as reading, writing, erasing, and the like, and an LCD controller 737 for controlling brightness or color of the LCD 738.

The present invention is not limited by the embodiments and drawings disclosed herein, and various modifications may be made by those skilled in the art within the technical scope of the present invention.

According to an embodiment of the present invention, a user can secure a desired usage time of a portable computer system by simply inputting desired time information without inputting complicated setting information. To this end, an embodiment of the present invention provides a use time input field in which a user can input a desired use time range and a user can input a use desired time. In addition, according to an embodiment of the present invention, by reducing the power level for a device that the user considers important later than other devices, the user can use the portable computer in a better environment for a desired time.

Claims (21)

Calculating a range of desired time of use using power consumption and remaining battery amount at the lowest power level of the portable computer system; Providing a usage time input box that enables a user to input the calculated usage time range and a usage time; Receiving a desired time of use from a user through the desired time input box; And If the total user time including the desired usage time exceeds the remaining time of this battery, the power level of the portable computer system is increased by reducing the power level of a device not selected by the user among the devices constituting the portable computer system. A method of power management of a portable computer system comprising the step of resetting. The method of claim 1, The desired use time input box includes a text box for receiving the desired use time in the form of a number. The method of claim 1, The desired time input field includes a slider having a continuous time value and a slider bar moving on the slider to determine the desired time value according to a user's selection. The method of claim 1, The calculating of the desired time range may include calculating power consumption of the portable computer system by setting power of each device included in the portable computer system to the lowest power level, and calculating the lowest power consumption and current remaining battery amount. Power management method for a portable computer system, characterized in that for calculating the desired time range using. delete delete The method of claim 1, Resetting the power level may set an initial power level of each device according to the desired time of use and the remaining time of the battery, and sequentially reduce the power level of each device, thereby reducing the power level of the portable computer system. A method of power management of a portable computer system comprising the step of resetting. The method of claim 1, And determining whether total user time is guaranteed after resetting the power level, and resetting the power level if the total user time is not guaranteed. Desired time input field to provide the user with a range of desired time calculated using power consumption and remaining battery power at the lowest power level of the portable computer system, and to input desired time according to the user's selection A user graphical interface including checkboxes for selecting importance of devices included in the portable computer system; And If the total user time including the desired usage time received through the user graphical interface exceeds the remaining time of the battery, resetting the power level of the portable computer system by reducing the power level from the unchecked device in the checkbox. A power management device for a portable computer system comprising a power manager. The method of claim 9, The desired time input box includes a text box for inputting a time in the form of a number. The method of claim 9, And the desired time input box includes a slider having a continuous time value and a slider bar moving on the slider to determine a desired time value according to a user's selection. delete The method of claim 9, The power manager is configured to reset the power level of the portable computer system by setting an initial power level of each device according to the desired use time and the remaining time of the battery, and sequentially decreasing the power level of each device. The power management device of the system. The method of claim 9, The power manager determines whether the total user time is guaranteed after resetting the power level, and resets the power level again when the desired time is not guaranteed. A battery unit for supplying power; A plurality of devices each providing a predetermined function; Usage time input box and the portable computer, which provide the user with a range of usage time calculated using the power consumption at the system's lowest power level and the remaining battery amount, and input the usage time according to the user's selection. A user graphical interface including a check box for selecting the importance of devices included in the system; And If the total user time including the desired usage time received through the user graphical interface exceeds the remaining time of the battery unit, the power level of the portable computer system is reduced by reducing the power level from the unchecked device in the checkbox. A portable computer system comprising a power manager to reset. The method of claim 15, The desired time input box includes a text box for inputting time in numerical form. The method of claim 15, And wherein the desired time input field includes a slider having a continuous time value and a slider bar moving on the slider to determine a desired time value according to a user's selection. delete The method of claim 15, The power manager is configured to reset the power level of the portable computer system by setting an initial power level of each device according to the desired use time and the remaining time of the battery, and sequentially decreasing the power level of each device. system. The method of claim 15, The power manager determines whether the desired use time is guaranteed after resetting the power level, and resets the power level again when the total user time is not guaranteed. A medium on which a computer-readable program is recorded for executing the method of any one of claims 1 to 4, 7, and 8.

Images